posted on 2019-04-29, 19:33authored byYi-Min Lin, Chen Song, Gregory C. Rutledge
Membrane-based separation is an important
technique for removing emulsified oil from water. However, the mechanisms
of fouling are complex because of the deformability and potential
for coalescence and break-up of the oil droplets. Here, we report
for the first time direct, three-dimensional (3D) visualization of
oil droplets on electrospun fiber microfiltration membranes after
a period of membrane-based separation of oil-in-water emulsions. High-resolution
3D images were acquired by a dual-channel confocal laser scanning
microscopy (CLSM) technique in which both the fibers and the oil (dodecane)
were fluorescently labeled. The morphology of dodecane as the foulant
was observed for two different types of fibers, an oleophobic nylon
(PA6(3)T), and oleophilic polyvinylidene fluoride (PVDF). Through
direct visualization, the rejected oil was found to form droplets
of clam-shell shape on the PA6(3)T fibers, whereas the oil tended
to wet the PVDF fibers and spread across the membrane. The morphology
was also analyzed as a function of separation time (i.e., “4D”
imaging), as the oil accumulated within and upon the membranes. The
observations are qualitatively consistent with a transition from blocking
of individual pores in the membrane to coalescence of oil droplets
into coherent liquid films with increasing filtration time. Analysis
of permeate flux using blocking filtration models corroborate the
transition of fouling modes indicated by the 3D images. This direct,
3D visualization CLSM technique is a powerful tool for characterizing
the mechanisms of fouling in membranes used for liquid emulsion separations.